He hydrogen It is becoming widely known worldwide in the exhaustive search for more sustainable forms of energy. That’s why we’ve already witnessed projects like the Arctic Ocean expedition at the edge of the planet. Under these circumstances, they managed to double the H ‘out of nowhere’. To achieve this they used the same chemical that gives energy to the body.
The commitment to low-carbon H plays a fundamental role in the current context. It is a unique fuel that offers great potential to limit climate change and its development.
It can help accelerate the decarbonization of difficult sectors, such as heavy industry and global transport.
With the help of this chemical, hydrogen appears out of nowhere
A Japanese company has started mass production of the carrier hydrogen next generation capable of multiplying the amount of stored H2 by two. Tokuyama has begun mass production of magnesium hydride, a breakthrough in the evolution of H storage and transport.
According to the information provided by the company, this is a connection chemical has the potential to release twice as much hydrogen than initially stores it, a phenomenon generated by interacting with water to release H2.
Magnesium hydride is a carrier of hydrogen more efficient than others we find on the market, such as compressed H or ammonia. In your case it is possible to store H2 on a volume basis. This is achieved through an innovative process developed in collaboration with Organic cola Giken Co.a method in which a byproduct of the chlor-alkali process reacts with solid magnesium.
This reaction produces magnesium hydride on the metal surface and encapsulates the magnesium molecule. hydrogen for storage or transport at room temperature and atmospheric pressure. The H recovery process is equally impressive because mixing magnesium hydride with water releases H molecules to form magnesium hydroxide.
This chemical stores hydrogen, accomplishing something never seen before
This interaction releases twice as many molecules hydrogen thanks to the H ions present in water (H2O). Tokuyama has set itself the target of producing 30 tons of magnesium hydride per year, an amount equivalent to 2.28 tons of magnesium hydride hydrogen and the capacity to generate 4.56 tons of H2 per year.
With a clear goal and method to achieve it, this invention is seen as a breakthrough storage solution hydrogen. This compound acts as an effective carrier for molecules of hydrogen and offers a safe and economical alternative for gas transport, especially compared to ammonia.
Challenges for the chemist who wants to transport hydrogen
Despite its benefits, magnesium hydride poses major safety challenges. Dust or particles emanating from the compound can be highly explosive if they come into contact with water and under certain conditions there is a risk of airborne ignition. This volatility has raised questions about the viability of maritime transport.
The development of Tokuyama It is an important promise in the current energy scenario. The search for more efficient and safer processes for storage and transport hydrogen It is active and there are high expectations for this solution.
Apparently this chemical has a lot of potential hydrogen. However, to make this solution viable, technical and safety issues must be overcome and energy efficiency and sustainability must be prioritized. Did you like this article? Then you shouldn’t miss what we have to tell you about solid hydrogen.